Understanding Stokes Theorem and Circulation

To find the divergence of a vector field.

To calculate the circulation of a vector field around a curve.

To determine the gradient of a scalar field.

To evaluate the potential energy in a field.

Green's Theorem applies to three-dimensional surfaces.

Stokes Theorem is used only for conservative fields, unlike Green's Theorem.

Green's Theorem is a special case of Stokes Theorem in two dimensions.

Both theorems are used to calculate surface areas.

The divergence and curl of a vector field.

The line integral around a closed curve and the surface integral over the surface it encloses.

The flux through a surface and the circulation around its boundary.

The gradient and potential of a scalar field.

The field has a constant magnitude.

It means the field has no divergence.

The line integral between any two points depends on the path taken.

The line integral around a closed curve is zero.

It determines the divergence of the field.

It is used to calculate the curl of the field.

It defines the path of integration.

It provides the values needed to evaluate the line integral.

When the surface is not smooth.

When the curve is not closed.

When the vector field is conservative.

When the vector field is non-conservative.

The curve is not smooth.

The field has no curl.

The potential function values at the start and end points are the same.

Because the field is not defined on the curve.

It is always zero.

It depends on the path taken.

It is equal to the surface integral over the enclosed surface.

It is equal to the divergence of the field.

The potential energy of the field.

The gradient of the field.

The net rotation of the field along the curve.

The total divergence of the field.

It is equal to the divergence of the field.

It is always zero.

It depends on the shape of the curve.

It is equal to the surface integral over the surface.